KR20120048686A - Focal plane shutter and optical device using same - Google Patents

Abstract

The focal plane shutter of the present embodiment includes a substrate having an opening, a blade capable of opening and closing the opening, a driving member movable between the start end position and the end position, biased toward the end position side, and driving the blade, and the end end. A braking member which is abutted and retractably supported by the driving member in a position and is urged to abut on the driving member in the termination position, and rotates in only one direction, and the driving member is started from the termination position. And a set member for moving to the position, wherein the set member is brought into contact with the braking member to retract the braking member from the driving member, and then touches the driving member to move the driving member to the start position. Have

Description

Focal plane shutter and optical device having same {FOCAL PLANE SHUTTER AND OPTICAL DEVICE USING SAME}

The present invention relates to a focal plane shutter and an optical device having the same.

The focal plane shutter is provided with a set member for moving the drive member for driving the blade from the end position to the start position (see Patent Document 1). Some focal plane shutters include a braking member from the viewpoint of preventing the driving member from bounding (see Patent Document 2). The braking member has a function of preventing the drive member moved from the start position to the end position to be bound at the end position by abutting with the drive member at the end position.

Japanese Patent Publication No. 2009-31513 Japanese Patent Publication No. 2001-21947

The movement from the end position of the drive member to the start position is performed by retracting the braking member from the drive member and then moving the drive member to the start position. The set member is provided with a portion which abuts against the brake member to retract the brake member from the drive member, and a portion that abuts against the drive member to move to the start position. As a result, the structure of the set member is complicated, and the size of the set member is increased.

Therefore, an object of the present invention is to provide a miniaturized focal plane shutter and an optical device.

The said objective is a board | substrate with an opening, the blade which can open and close the said opening, the drive member which can move between a start end position and a termination position, is biased toward the said termination position side, and drives a blade, and the said termination A braking member which is abutted and retractably supported by the driving member in a position and is urged to abut on the driving member in the termination position, and rotates in only one direction, and the driving member is started from the termination position. And a set member for moving to the position, wherein the set member is brought into contact with the braking member to retract the braking member from the driving member, and then touches the driving member to move the driving member to the start position. It can be achieved by a focal plane shutter having a.

Thereby, the single drive part provided in the set member withdraws a braking member from the drive member in a terminal position, and moves a drive member to a start position. Thereby, it is not necessary to separately install the part which retracts a brake member from a drive member, and the part which moves a drive member to a start position to a set member. Therefore, the set member can be downsized, and the focal plane shutter can be downsized.

The said structure WHEREIN: The iron piece provided in the said drive member, and the electromagnet which can adsorb | suck the said iron piece of the said drive member in the said start position, The said drive part retracts from the said braking member and the said drive member, And the structure which allows the movement to the said terminal position from the said starting position of the said drive member based on the interruption of the electricity supply to the said electromagnet can be employ | adopted.

As a result, the blade can be operated by a single drive unit, and the focal plane shutter can be miniaturized.

The above object can also be attained by an optical apparatus provided with the focal plane shutter.

According to the present invention, it is possible to provide a miniaturized focal plane shutter and an optical device having the same.

1 is a front view of a focal plane shutter of this embodiment.
2 is a schematic diagram of a focal plane shutter.
3 is a side view of the focal plane shutter.
4 is an explanatory diagram of the operation of the focal plane shutter.
5 is an explanatory diagram of the operation of the focal plane shutter.
6 is an explanatory diagram of a transition to an initial state.
7 is an explanatory diagram of a transition to an initial state.
8 is an explanatory diagram of transition to an initial state.
9 is an explanatory diagram of transition to an initial state.
It is explanatory drawing of the transition to an initial state.
It is explanatory drawing of the transition to an initial state.

Hereinafter, embodiments will be described with reference to the drawings.

In this embodiment, the focal plane shutter will be described. 1 is a front view of a focal plane shutter of this embodiment. FIG. 2 is a schematic diagram of a focal plane shutter, and a part of the configuration shown in FIG. 1 is omitted. In FIG. 3 is a side view of the focal plane shutter.

As shown in Fig. 1, the focal plane shutter includes a substrate 10, a leading blade 20A, a trailing blade 20B, drive arms 31a, 32a, 31b, 32b. And a drive lever 40A, a drive lever 40B, an electromagnet 70A, and an electromagnet 70B. The substrate 10 is made of synthetic resin and has a rectangular opening 11.

The leading blade 20A and the trailing blade 20B are each composed of a plurality of blades, and only blades 21a and 21b are shown in FIG. 1. Each blade is made of synthetic resin and is thinly formed. The leading blade 20A is connected to the drive arms 31a and 32a, and the trailing blade 20B is connected to the drive arms 31b and 32b. The drive arms 31a, 32a, 31b and 32b are formed of a thin plate of metal. The driving arms 31a, 32a, 31b, and 32b are freely supported on the substrate 10 by swinging, respectively.

The leading blade 20A and the trailing blade 20B respectively move between the position retracted from the opening 11 and the position of closing the opening 11. Moreover, in the position which retracted from the opening 11, the some blade which comprises each blade overlaps, and in the position which closes the opening 11, a some blade develops. In the case of FIG. 1, the leading blade 20A is developed to close the opening 11, and the trailing blade 20B is retracted from the opening 11. In FIG. 1, although it mentions later in detail, the leading blade 20A and the trailing blade 20B have shown the initial state located at the start position of the movement range, respectively.

The board | substrate 10 is provided with the drive lever 40A and the drive lever 40B for driving the drive arms 32a and 32b, respectively. The drive lever 40A and the drive lever 40B are rotatably supported with respect to the axis formed in the board | substrate 10, respectively. As shown in Fig. 2, the drive lever 40A is provided with a drive pin 43a fitted with the drive arm 32a, and the drive lever 40B has a drive pin 32 fitted with the drive arm 32b. 43b) is installed. Arc-shaped exit holes 13a and 13b are formed in the substrate 10. The drive pins 43a and 43b move in escape slots 13a and 13b, respectively. As a result, the swing ranges of the drive lever 40A and the drive lever 40B are defined. Further, rubber for preventing the bound is provided at the terminal portions of the exit holes 13a and 13b. The drive lever 40A and the drive lever 40B are made of synthetic resin.

As the drive lever 40A swings, the drive arms 31a and 32a swing and the leading blade 20A moves. The drive lever 40A is a leading blade drive member. Similarly, when the drive lever 40B swings, the drive arms 31b and 32b swing and the trailing blade 20B moves. The drive lever 40B is a trailing blade drive member.

Next, the driving lever 40A and the driving lever 40B will be described. As shown in FIG. 2, the drive lever 40A is rotatably supported by the base part 41a formed in the substantially flat shape, the cylinder part 42a installed on the base part 41a, and the base part 41a. (roller) 46a, support wall 44a for holding the iron piece 45a. The iron piece 45a is being fixed to the tip of the pin which penetrated the support wall 44a. The drive lever 40B is also comprised similarly. 40 A of drive levers can rock between the positions with which the iron piece 45a was evacuated from the position which abuts the electromagnet 70A. The same applies to the drive lever 40B.

The drive lever 40A is biased from the start position to the end position of the movement range by the spring 54A shown in FIG. 3. The start position is a position where the driving lever 40A abuts on the electromagnet 70A. The end position is a position at which the drive lever 40A is withdrawn from the electromagnet 70A. In other words, the driving lever 40A is biased in the direction away from the electromagnet 70A by the spring 54A. Similarly, the drive lever 40B is also urged from the start position of the movement range to the end position by the spring 54B. The springs 54A and 54B are wound around the outer circumferential side of the cylinders 42a and 42b, respectively.

One end of the spring 54A is engaged with the drive lever 40A, and the other end of the spring 54A is engaged with the ratchet wheel 50A. Although the ratchet wheel 50A is not shown in FIG. 1, FIG. 2, as shown in FIG. 3, it is rotatably connected to the upper end side of the cylinder part 42a. By adjusting the amount of rotation of the ratchet wheel 50A, the bias force of the spring 54A can be adjusted. The ratchet wheel 50B and the spring 54B also have the same function.

3 is provided with pawl portions 99a and 99b for stopping the rotation of the ratchet wheels 50A and 50B, respectively. The rough portions 99a and 99b are integrally provided on the holding plate 90 disposed to face the substrate 10. The holding plate 90 is made of a metal that can be elastically deformed. The printed board 100 is fixed to the upper surface side of the holding plate 90. The printed circuit board 100 is for energizing and controlling the electromagnets 70A and 70B.

70 A of electromagnets are energized, and the iron piece 45a of the drive lever 40A can be adsorb | sucked. Similarly, the electromagnet 70B is also energized, so that the iron piece 45b of the drive lever 40B can be attracted.

The electromagnet 70A is provided with a coil wound around the iron core 76a and exciting the iron core 76a. In FIG. 1, FIG. 2, the coil is abbreviate | omitted. The coil is electrically connected to the pattern of the printed circuit board 100. By changing the energization of the coil, the iron core 76a is excited or demagnetized. The electromagnet 70B is similarly comprised.

The set member 60 rotates in one direction by receiving a rotational movement force from a gear not shown. The set member 60 positions the drive lever 40A and the drive lever 40B at their respective start positions. The set member 60 is in contact with the braking members 80A and 80B. The set member 60 has drive cams 62a and 62b and a gear portion 68 as shown in FIGS. 1 and 3. As shown in FIG. 3, the drive cams 62a and 62b and the gear portion 68 are lined up in the optical axis direction OD. In other words, the drive cams 62a and 62b and the gear portion 68 have different height positions in the optical axis direction. The gear portion 68 rotates in one direction in engagement with a gear not shown. The drive cam 62a includes a protruding surface 62a1 along a circumference around the center of rotation of the set member 60, a retracted surface 62a0 retreating inwardly of the circumference, a protruding surface 62a1 and a retracted surface The working surface 62a2 between 62a0 is provided. The protruding surface 62a1 protrudes outward in the radial direction of the rotation center of the set member 60. The retraction surface 62a0 retreats radially outward from the protruding surface 62a1. The drive cam 62a is able to contact the roller 46a at the protruding surface 62a1 and the working surface 62a2.

Similarly, the drive cam 62b includes a protruding surface 62b1 along the circumference around the center of rotation of the set member 60, a receding surface 62b0 retracted inwardly of the circumference, the protruding surface 62b1 and the above-mentioned. A working surface 62b2 is provided between the retracted surfaces 62b0. The protruding surface 62b1 protrudes radially outward of the rotation center of the set member 60. The retraction surface 62b0 retreats radially outward from the protruding surface 62b1. The drive cam 62b is able to contact the roller 46b at the protruding surface 62b1 and the acting surface 62b2. As shown in FIG. 1, FIG. 2, the drive cam 62a, 62b which is a drive part is formed in substantially fan shape. As the set member 60 rotates, the drive cams 62a and 62b abut and retract the rollers 46a and 46b, respectively. The rollers 46a and 46b are also provided in the position corresponding to the height position of the drive cams 62a and 62b in the optical axis direction. The rocking center of the braking member 80A and the rocking center of the drive lever 40A are lined up in the order of rotation direction of the set member 60. The same applies to the braking member 80B and the drive lever 40B.

As shown in FIG. 2, the braking members 80A and 80B are supported by the substrate 10 so as to be able to swing. The braking member 80A has a arm portion 81a, a cylinder portion 82a provided on the arm portion 81a, a pressurized portion 84a pressed by the drive cam 62a, and a blood pressure that can contact the drive lever 40A. It has a contact 88a. The cylinder part 82a fits slidably to the shaft provided in the board | substrate 10. FIG. The braking member 80A is biased to rotate clockwise by a spring Sa fixed to the substrate 10. The spring Sa is wound around the shaft formed in the substrate 10, one end of which is engaged with the braking member 80A, and the other end is fixed to the substrate 10.

The contact part 48a is provided in the bottom face side of the base part 41a. The contact portion 48a may be in contact with the contact portion 88a of the braking member 80A. Specifically, when the driving lever 40A is positioned at the terminal position, the contact portion 48a and the contact portion 88a abut.

Moreover, the braking member 80B has the cylinder part 82b, the to-be-pressed part 84b pressed by the drive cam 62b, and the to-be-contacted part 88b which can contact the drive lever 40B. The cylinder part 82b slidably fits the shaft provided in the board | substrate 10. FIG. The braking member 80B is urged counterclockwise by the spring Sb fixed to the substrate 10. It mentions later in detail. The contact part 48b is provided in the outer peripheral part of the cylinder part 42b of the drive lever 40B. The contact part 48b protrudes outward from the outer peripheral part of the cylinder part 42b. The contact portion 48b may be in contact with the contact portion 88b of the braking member 80B. In detail, when the drive lever 40B is positioned in the terminal position, the contact portion 48b and the contact portion 88b abut.

Next, the operation of the focal plane shutter will be described with reference to FIGS. 2, 4 and 5. When the release button of the camera is pressed at the time of shooting, the coils of the electromagnets 70A and 70B are energized in the state shown in Fig. 2 so that the iron pieces of the drive lever 40A are attracted to the electromagnet 70A, and the drive lever ( The iron piece of 40B is adsorbed by the electromagnet 70B. In the state shown in FIG. 2, the drive cams 62a and 62b are in contact with the rollers 46a and 46b, respectively.

Then, the set member 60 rotates clockwise from the state shown in FIG. When the set member 60 rotates in the clockwise direction, the protruding surface 62a1 of the drive cam 62a moves to the position retracted from the operation trajectory of the roller 46a to be spaced apart from the roller 46a, and the drive cam 62b. The protruding surface 62b1 of) moves to the position withdrawn from the operation trajectory of the roller 46b, and spaces apart from the roller 46b. In this state, the electricity supply to the electromagnet 70A is cut off, and the drive lever 40A swings clockwise according to the biasing force of the spring 54A. The drive lever 40A moves from the start position to the end position. The leading blade 20A which has closed the opening 11 retracts from the opening 11, and the opening 11 is in a developed state. 4 shows a state during exposure.

In addition, after the predetermined period has passed, energization of the electromagnet 70B to the coil is interrupted, and the drive lever 40B swings clockwise in accordance with the bias force of the spring 54B. The drive lever 40B moves from the start position to the end position. As a result, the opening 11 in the deployed state is closed by the trailing blade 20B. 5 shows a state immediately after the end of the exposure operation. In this manner, one shooting is completed.

The braking member 80A will be described.

When the drive lever 40A moves from the start end position to the end position, there is a fear that the drive pin 43a is in contact with and bound to the end portion of the exit hole 13a. The braking member 80A has a function of reducing the speed of the drive lever 40A and preventing the drive lever 40A from being bound. In the initial state shown in FIG. 2, the to-be-pressed part 84a of the braking member 80A is pressed by the drive cam 62a, and has shown the state rotated counterclockwise. That is, the state which made the braking member 80A rotate counterclockwise against the biasing force of the spring Sa is shown. Similarly, in the state shown in FIG. 2, the to-be-pressed part 84b of the braking member 80B is pressed by the drive cam 62b, and has shown the state rotated clockwise. That is, the state which made the braking member 80B rotate clockwise against the bias force of the spring Sb is shown.

When the set member 60 rotates in the clockwise direction from the state of FIG. 2, the protruding surface 62a1 of the drive cam 62a is evacuated from the pressed portion 84a of the braking member 80A, and the braking member 80A is Rotate slightly clockwise according to the spring force of spring Sa. As a result, the contact portion 88a of the braking member 80A is positioned on the track of the contact portion 48a. After that, when the set member 60 further rotates clockwise, the projecting surface 62a1 of the drive cam 62a is separated from the roller 46a as shown in FIG. 4. Here, when electricity supply to the coil of the electromagnet 70A is interrupted and the drive lever 40A held at the start end rotates clockwise along the spring 54A, the contact portion 48a is contacted portion 88a. In contact with the brake member 80A causes the braking member 80A to rotate counterclockwise against the biasing force of the spring Sa. When the contact portion 48a passes through the contact portion 88a, the braking member 80A is pushed back clockwise by the biasing force of the spring Sa. As a result, the rotation speed of the drive lever 40A decreases. When the contact portion 48a passes through the contact portion 88a, the contact portion 88a rotates clockwise again to abut on the contact portion 48a in a state located on the back side of the contact portion 48a. In other words, the contacted portion 88a prevents the movement of the drive lever 40A so that the drive lever 40A does not move in the start end position direction, that is, it does not rotate counterclockwise. This prevents the bound of the drive lever 40A in the end position. The braking member 80A is a leading blade braking member having a function of reducing the speed of the driving lever 40A and preventing the driving lever 40A from being bound.

The contact portion 88b of the braking member 80B and the contact portion 48b of the drive lever 40B also have the same function. When the set member 60 rotates clockwise from the state of FIG. 2, as shown in FIG. 4, the protruding surface 62b1 of the drive cam 62b is evacuated from the pressurized portion 84b of the braking member 80B. The braking member 80B rotates slightly counterclockwise in accordance with the biasing force of the spring Sb. As a result, the contact portion 88b of the braking member 80b is positioned on the track of the contact portion 48b. After that, when the set member 60 further rotates clockwise, the projecting surface 62b1 of the drive cam 62b is separated from the roller 46b as shown in FIG. 4. Here, when the electricity supply to the electromagnet 70B is cut off, the drive lever 40B rotates clockwise according to the spring 54B. Along with this, the contact portion 48b abuts against the contact portion 88b, and the braking member 80B is caused to rotate in a clockwise direction against the negative force of the spring Sb. When the contact portion 48b passes through the contact portion 88b, the braking member 80B is pushed back in the counterclockwise direction by the biasing force of the spring Sb. As a result, the rotational speed of the drive lever 40B decreases. When the contact portion 48b passes through the contact portion 88b, as shown in FIG. 5, the contact portion 88b is located on the rear side of the contact portion 48b such that the drive lever 40B is not bound in the end position. In contact with the contact portion 48b. In other words, the contact portion 88b prevents the movement of the drive lever 40B so that the drive lever 40B does not move in the start end position direction, that is, does not rotate counterclockwise. This prevents the bound of the drive lever 40B in the end position. The braking member 80B is a trailing blade braking member having a function of reducing the speed of the drive lever 40B and preventing the drive lever 40B from being bound.

The transition to the initial state will be described with reference to FIGS. 6 to 11.

From the state shown in FIG. 5, when the set member 60 rotates clockwise, the working surface 62a2 of the drive cam 62a abuts against the to-be-pressed part 84a of the braking member 80A, as shown in FIG. . In addition, when the set member 60 rotates clockwise, the braking member 80A is rotated counterclockwise as shown in Fig. 7 so that the contacted portion 88a retracts from the contact portion 48a. As a result, the drive lever 40A is in a state capable of moving from the end position to the start position. When the set member 60 rotates clockwise, the action surface 62a2 of the drive cam 62a abuts against the roller 46a to rotate the drive lever 40A counterclockwise, as shown in FIG. 8. As shown, the drive lever 40A is positioned at the start position.

In addition, when the set member 60 rotates clockwise, the working surface 62b2 of the drive cam 62b abuts against the press part 84b of the braking member 80B, as shown in FIG. When the set member 60 rotates, as shown in FIG. 10, the braking member 80B rotates clockwise so that the contacted portion 88b retracts from the contacted portion 48b. As a result, the drive lever 40B is in a state capable of moving from the end position to the start position. In addition, when the set member 60 rotates clockwise, the action surface 62b2 of the drive cam 62b abuts against the roller 46b to rotate the drive lever 40B counterclockwise, as shown in FIG. 11. As shown, the drive lever 40B is positioned at the start position. At this time, the driving lever 40A is held at the start position as described above by the drive cam 62a of the set member 60. As the braking members 80A and 80B are energized in this state, the iron pieces 45a and 45b are adsorbed and held by the iron cores 76a and 76b, respectively.

As described above, the drive lever 40A and the drive lever 40B can be positioned from the end position to the start position. While the set member 60 is rotated in the clockwise direction as described above, the drive cam 62a abuts on the braking member 80A to withdraw the braking member 80A from the drive lever 40A, and then the drive lever. In contact with 40A, the drive lever 40A is moved to the start position. In this manner, the single drive cam 62a retracts the braking member 80A and moves to the start position of the drive lever 40A. The drive cam 62b also has the same function.

Thereby, the set member 60 of this embodiment is compared with the case where the drive member for retracting the braking member 80A from the drive lever 40A and the drive unit for moving the drive lever 40A to the start position are separately provided on the set member. The structure is simplified and miniaturized. As a result, the focal plane shutter of the present embodiment is downsized.

For example, in the case where the drive cam for retracting the braking member 80A from the drive lever 40A and the drive cam for moving the drive lever 40A are separately provided to the set member that rotates in only one direction, both drive cams are provided. It is necessary to install so that it may line up in the optical axis direction. This is because the driving portion for retracting the braking member 80A is avoided from contacting the driving lever 40A while the set member is rotating in one direction. This is because the driving cam for moving the driving lever 40A is prevented from contacting the braking member 80A. Moreover, it is necessary to provide the set member together with the drive cam which moves the braking member 80B from the drive lever 40B, and the drive cam which moves the drive lever 40B together. Therefore, the set member needs to be provided so that four drive cams line up in the optical axis direction, and the set member is particularly large in the optical axis direction.

In this embodiment, the braking members 80A and 80B can be retracted by the two drive cams 62a and 62b, and the drive lever 40A and the drive lever 40B can be moved. As a result, the size of the set member 60 is particularly small in the optical axis direction. Therefore, the focal plane shutter of this embodiment is thinned in the optical axis direction.

As mentioned above, although preferred embodiment of this invention was described above, this invention is not limited to the specific embodiment concerned, A deformation | transformation and a change are possible in the range of the summary of this invention described in the claim.

The focal plane shutter of the present embodiment can be employed in an optical device such as a camera or a digital camera.

In the above embodiment, the case where each blade constituting the leading blade and the trailing blade is made of synthetic resin has been described, but each blade may be metallic.

Claims (5)

A substrate having an opening,
A blade capable of opening and closing the opening;
A drive member movable between the start end position and the end position, biased toward the end position, and for driving the blade;
A braking member that is abutted and retractably supported by the drive member in the termination position and is urged to abut on the drive member in the termination position;
A set member which rotates in only one direction and moves the drive member from the end position to the start position,
And the set member has a driving portion that abuts against the braking member to retract the braking member from the driving member, and then touches the driving member to move the driving member to the start position. The method of claim 1,
An iron piece provided on the driving member,
An electromagnet capable of adsorbing the iron piece of the drive member at the start end position;
And the drive portion is retracted from the braking member and the drive member to allow movement from the start end position of the drive member to the end position based on the interruption of energization to the electromagnet. The method according to claim 1 or 2,
The drive section includes a protruding surface protruding radially outward from the rotational center of the set member, a retracted surface retracted radially inward from the protruding surface, and an operating surface between the protruding surface and the retracted surface. One drive cam,
The protruding surface maintains the braking member in the retracted position withdrawn from the drive member and holds the drive member in the start position,
The evacuation surface allows movement of the braking member and the driving member without contacting the braking member and the driving member,
And the working surface retracts the braking member from the driving member and moves the driving member from the end position to the start position. The method according to claim 1 or 2,
The blade includes a leading blade and a trailing blade,
The driving member includes a leading blade driving member and a trailing blade driving member for driving the leading blade and the trailing blade, respectively,
The braking member includes a leading blade braking member and a trailing blade braking member, which are in contact with each of the leading blade driving member and the trailing blade driving member, and are retractable;
The driving unit includes a leading blade driving unit and a trailing blade driving unit,
The leading blade drive portion is brought into contact with the leading blade braking member to retract the leading blade braking member from the leading blade drive member, and then contacted with the leading blade drive member to move the leading blade drive member to the start position. ,
The trailing blade drive unit abuts the trailing blade braking member to retract the trailing blade braking member from the trailing blade drive member and then abuts the trailing blade drive member to contact the trailing blade drive member. Focal plane shutter for moving to the start position. An optical device comprising the focal plane shutter of claim 1.

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